Document Type
Research Report
Publication Date
6-25-2024
Abstract
This report presents the methods we developed to calculate risk of mixtures of pesticides for the Upper San Francisco Estuary (USFE). We used curve fitting to estimate the exposure-response curves for each individual chemical and then the mixture. For the mixtures, the models were normalized for specific ECx values. In that way, the curve fitting was optimized for effects that are comparable to most threshold values. A Bayesian network was built that incorporated five different pesticides and mercury. The input distributions of the contaminants were measured amounts from each of the six risk regions. We also explored three different methods of combining the results of the three pathways – additive, average, and expert judgement. The initial result was the BN model’s Predicted Fish Mortality (%). The Sensitivity analysis (mutual information) identified the most important components of the Bayesian network in determining the toxicity. The top two pathways were the Malathion/Diazinon Mortality pathway and the Mercury Mortality pathway. For the individual nodes Mercury, Bifenthrin and Season were key. Currently, we are completing the risk assessment network by adding Chinook salmon and Delta smelt population pathways to estimate risk to the six Risk Regions. A major accomplishment was the demonstration that curve fitting using additive models for mixtures can be used to estimate fish toxicity in this proof-of-concept model. Bifenthrin, the specific risk region, and season were the inputs that were most important to the calculation. Factors determining macroinvertebrate community structure were identified using multivariate tools. Water quality parameters were the most important in determining clusters of similar macrobenthic communities. Because contaminants were not statistically significant in determining these patterns, further analysis of macroinvertebrate community structure was not conducted. At this time, the techniques applied in this program appear applicable to estimating risk due to the variety of chemicals and other stressors to the multiple endpoints under management in the USFE.
Recommended Citation
Landis, Wayne; Lawrence, Eric J.; Bowers, Mikayla; Brown, Ethan; Eikenbary, Steven R.; Elmstrom, Skyler; Lemons, Colter; Markiewicz, April J.; Sharpe, Emma E.; and Whitney, Erika, "The Relative Contributions of Contaminants to Ecological Risk in the Upper San Francisco Estuary" (2024). Institute of Environmental Toxicology & Chemistry Publications. 14.
https://cedar.wwu.edu/ietc_allpublications/14
Subjects - Topical (LCSH)
Pollutants--Environmental aspects--California--San Francisco Bay Area--Measurement; Marine pollution--California--San Francisco Bay Area--Mathematical models; Fishes--Effect of water pollution on--Mathematical models; Bayesian statistical decision theory
Geographic Coverage
San Francisco Bay Watershed (Calif.)--Environmental conditions
Genre/Form
technical reports; memorandums
Type
Text
Rights
Copying of this document in whole or in part is allowable only for scholarly purposes. It is understood, however, that any copying or publication of this document for commercial purposes, or for financial gain, shall not be allowed without the author’s written permission.
Language
English
Format
application/pdf
Included in
Ecology and Evolutionary Biology Commons, Environmental Health Commons, Toxicology Commons